U.S. patent application number 12/044427 was filed with the patent office on 2013-01-03 for method of manufacturing magnetoresistive element.
This patent application is currently assigned to TDK CORPORATION. Invention is credited to Masaru HIROSE, Shunji SARUKI, Takumi YANAGISAWA.
Application Number | 20130000103 12/044427 |
Document ID | / |
Family ID | 47389135 |
Filed Date | 2013-01-03 |
United States Patent
Application |
20130000103 |
Kind Code |
A1 |
YANAGISAWA; Takumi ; et
al. |
January 3, 2013 |
METHOD OF MANUFACTURING MAGNETORESISTIVE ELEMENT
Abstract
The method according to the present invention includes the steps
of: sequentially applying a plurality of different voltages to an
MR element and sequentially detecting output signals from the MR
element; and eliminating the MR element as a defective product when
an evaluation value, based on a difference of SN ratios of the
output signals from the MR element respectively obtained for each
applied voltage, is less than a threshold value, and selecting the
MR element as a non-defective product when the evaluation value is
greater than or equal to the threshold value.
Inventors: |
YANAGISAWA; Takumi; (Tokyo,
JP) ; HIROSE; Masaru; (Tokyo, JP) ; SARUKI;
Shunji; (Tokyo, JP) |
Assignee: |
TDK CORPORATION
Tokyo
JP
|
Family ID: |
47389135 |
Appl. No.: |
12/044427 |
Filed: |
March 7, 2008 |
Current U.S.
Class: |
29/593 ;
324/537 |
Current CPC
Class: |
Y10T 29/49004 20150115;
Y10T 29/49032 20150115; G01R 19/00 20130101; G01R 15/00 20130101;
G11B 5/3196 20130101; G11B 5/3173 20130101; G11B 5/3166 20130101;
G11B 5/127 20130101; G11B 5/455 20130101; G01R 3/00 20130101; G11B
5/3903 20130101; Y10T 29/49036 20150115; Y10T 29/49037
20150115 |
Class at
Publication: |
29/593 ;
324/537 |
International
Class: |
G01R 31/02 20060101
G01R031/02; G11B 5/127 20060101 G11B005/127 |
Claims
1. A method of manufacturing a magnetic device, comprising the
steps of: (a) sequentially applying a plurality of different
voltages to an MR element and sequentially detecting output signals
from the MR element, and (b) eliminating the MR element as a
defective product when at least one evaluation value based on a
difference of SN ratios of the output signals from the MR element
respectively obtained for each applied voltage, is less than a
first threshold value, and selecting the MR element as a
non-defective product when the at least one evaluation value is
greater than or equal to the first threshold value.
2. The method of manufacturing a magnetic device according to claim
1, wherein the evaluation value is a difference of the SN
ratios.
3. The method of manufacturing a magnetic device according to claim
1, further comprising a step of eliminating the MR element as a
defective product when the number of evaluation values is plural
and an evaluation value different from the evaluation value of the
step (b) is less than a second threshold value, even if the
evaluation value of the step (b) is greater than or equal to the
first threshold value.
4. The method of manufacturing a magnetic device according to claim
1, further comprising a step of attaching the MR element selected
as the non-defective product in the step (b) to a head gimbal
assembly.
5. The method of manufacturing a magnetic device according to claim
1, wherein the step (a) is performed after the MR element is
attached to the head gimbal assembly.
6. An inspection device for an MR element comprising: detection
means for sequentially applying a plurality of different voltages
to the MR element and sequentially detecting output signals from
the MR element; and calculation means for determining the MR
element to be a defective product when an evaluation value, based
on a difference of SN ratios of the output signals from the MR
element respectively obtained for each applied voltage which are
detected by the detection means, is less than a first threshold
value, and determining the MR element to be a non-defective product
when the evaluation value is greater than or equal to the first
threshold value.
Description
BACKGROUND OF THE INVENTION
[0001] 1. Field of the Invention
[0002] The present invention relates to a method of manufacturing a
magnetic device having a magnetoresistive (MR) element, and to an
inspection device therefor.
[0003] 2. Related Background Art
[0004] Recently, as a magnetic head structure, a structure in which
a heater is incorporated into a magnetic head has been proposed
(U.S. Pat. No. 5,991,113), while conventionally a magnetic head in
which a heater is not incorporated has been well known. A magnetic
head such as a heat-assisted magnetic head which allows a rise in
the temperature of the magnetic head has also been proposed
(Japanese Unexamined Patent Publication No. 2006-185548).
[0005] The inventor(s) of the present invention have worked on the
development of magnetic heads, and found that there were, among
manufactured magnetic heads, defective magnetic heads which had an
increased noise component as the temperature increased while
functioning normally at room temperature. In other words, it was
found that there were magnetic heads in which the magnitude of the
noise component included in the output signals from the magnetic
heads was larger than a stipulated value when the temperature
increased.
SUMMARY OF THE INVENTION
[0006] The inventor(s) of the present invention have attempted to
eliminate, as defective products, defective magnetic heads having
signal-to-noise (SN) ratios below or equal to a stipulated value at
a high temperature in the magnetic head manufacturing process.
However, manufacturing throughput deteriorates when a step of
raising the temperature for SN ratio inspection is carried out. The
inventors of the present invention have devised a method in which
defective products having SN ratios below or equal to the
stipulated value at high temperatures are sorted at room
temperature. As this kind of method does not require the step of
raising the temperature for SN ratio inspection, manufacturing
throughput can be improved. Specifically variation of the SN ratio
of an MR element, which becomes defective at a high temperature,
becomes smaller than the variation of the SN ratio of a
non-defective product when an applied voltage to the MR element is
varied.
[0007] This inspection step for the method of manufacturing an MR
element comprises the steps of varying the applied voltage to the
MR element; and eliminating the MR element as a defective product
when an evaluation value, based on the variation of the SN ratios
obtained before and after the varying of the applied voltage, is
smaller than a threshold value. This evaluation value may include a
correction factor when required.
BRIEF DESCRIPTION OF THE DRAWINGS
[0008] FIG. 1 is a perspective view of a hard disk device;
[0009] FIG. 2 is a perspective view of an HGA;
[0010] FIG. 3 is a perspective view of a magnetic head;
[0011] FIG. 4 is an enlarged perspective view of a magnetic head
portion;
[0012] FIG. 5 is a block diagram of an inspection device;
[0013] FIG. 6 is a flow chart of a determination;
[0014] FIG. 7 is a graph showing a relationship of applied voltage
and .DELTA.SN;
[0015] FIG. 8 is a graph showing a relationship of applied voltage
and .DELTA.SN;
[0016] FIG. 9 is a graph showing a relationship of applied voltage
and S*;
[0017] FIG. 10 is a graph showing a relationship of applied voltage
and N*;
[0018] FIG. 11 is a table showing a relationship of S*, N*, and
.DELTA.SN for each sample for different applied voltages;
[0019] FIG. 12 is a table showing a relationship of S, N, and SN
for each sample for different applied voltages;
[0020] FIG. 13 is a perspective view of a magnetic head bar;
[0021] FIG. 14 is a flow chart of a method of manufacturing;
[0022] FIG. 15 is a perspective view of a wafer;
[0023] FIG. 16 is a flow chart of a method of manufacturing;
[0024] FIG. 17 is a flow chart of a method of manufacturing;
and
[0025] FIG. 18 is a flow chart of a method of manufacturing.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0026] FIG. 1 is a perspective view of a hard disk device according
to an embodiment.
[0027] A hard disk device 100 comprises magnetic disks 10 which are
a plurality of magnetic recording media which are rotated around a
rotating shaft of a spindle motor 11, an assembly carriage device
12 for positioning a magnetic head 21 on a track, and a control
circuit 13 which performs recording/reproducing by controlling
write and read operations of this magnetic head 21.
[0028] A plurality of drive arms 14 are provided in the assembly
carriage device 12. These drive arms 14 can be swung about a
pivot-bearing axis 16 by means of a voice coil motor (VCM) 15 and
are stacked in a direction along this axis 16. A head gimbal
assembly (HGA) 17 is attached to a tip end portion of each drive
arm 14. The magnetic head 21 is provided in each HGA 17 so as to
face the front surface of the magnetic disk 10. The surface facing
the front surface of the magnetic disk 10 is a media-facing surface
S of the magnetic head 21 (also called an air bearing surface, see
FIG. 2). Note that, the magnetic disks 10, the drive arms 14, the
HGAs 17, and the magnetic heads 21 may be provided singularly.
[0029] FIG. 2 is a perspective view of the HGA 17. The media-facing
surface S of the HGA 17 is shown facing upward in this drawing.
[0030] The HGA 17 is configured by fixing a magnetic head 21 to a
tip end portion of a suspension 20, and electrically connecting one
end of a wire member 203 to a terminal electrode of this magnetic
head 21. The suspension 20 is mainly configured from a load beam
200, an elastic flexure 201 fixed onto and supported by this load
beam 200, a tongue portion 204 formed on a tip end of the flexure
in the shape of a leaf spring, a base plate 202 provided at a base
portion of the load beam 200, and a wire member 203 provided on the
flexure 201 and formed from a lead conductor and a connection pad
electrically connected to both ends of the lead conductor.
[0031] Note that the structure of the suspension in the HGA 17 is
clearly not limited to the above-described structure. Also note
that while not shown in the drawing, an IC chip for head drive may
be mounted in the middle of the suspension 20.
[0032] FIG. 3 is a perspective view of the magnetic head 21.
[0033] A magnetic head portion 1 is fixed to one end of a slider
substrate 2. A pattern, not shown in the drawing, for floating the
magnetic head stably when the magnetic disk is rotated, is formed
in a media-facing surface S of the slider substrate. The slider
substrate 2 is formed from AlTiC (Al.sub.2O.sub.3--TiC) for
example. When a highly heat-conductive substrate is used as the
slider substrate 2, the substrate has a heat dissipation
function.
[0034] The magnetic head portion 1 comprises a writing element 1A
for magnetic information, and an MR element 1B which is a reading
element for magnetic information. The tip end of the writing
element 1A and the magnetosensitive surface of the MR element 1B
are positioned on the same side as the media-facing surface S. The
arrangement direction of the writing element 1A and the MR element
1B is along the track of the magnetic disk 10, and in the
media-facing surface S a width direction perpendicular to this
arrangement direction is the track width direction. When setting an
X-Y-Z rectangular coordinate system as shown in the drawing, the
above-described arrangement direction corresponds to the X-axis
direction, and the track width direction corresponds to the Y-axis
direction.
[0035] FIG. 4 is an enlarged perspective view of the magnetic head
portion.
[0036] The magnetic head portion 1 comprises a magnetic shield
layer SL between a lower insulation layer IL1 and an upper
insulation layer IL2. The MR element 1B is embedded in the lower
insulation layer IL1 of the slider substrate 2 side of the magnetic
shield layer SL, and the writing element 1A is embedded in the
upper insulation layer IL2. End surfaces of both the MR element 1B
and the writing element 1A are exposed in the media-facing surface
S.
[0037] The writing element 1A has a main pole P1 and an auxiliary
pole P2, and a coil CL is provided to enclose the magnetic flux
passing through these poles. A heater HT is embedded in the
insulation layer of the lower portion of the coil CL. Although as
the present example, a magnetic head portion comprising a heater HT
is shown in the drawing, the present invention can also be applied
to a magnetic head portion not comprising a heater. The writing
element 1A employs a perpendicular magnetic recording method,
however it can use a longitudinal magnetic recording method, and a
heat-assisted magnetic recording method can also be applied. U.S.
Pat. No. 5,991,113 is incorporated herewith by reference as a
detailed structure of a magnetic device comprising a heater,
however a heater of a pulse waveform shape or a heater of an
interdigital structure can also be employed.
[0038] The MR element 1B is formed from an upper shield electrode
1B.sub.U, a lower shield electrode 1B.sub.L, and an MR element film
interposed between the upper shield electrode 1B.sub.U and the
lower shield electrode 1B.sub.L. The MR element film of the present
example is a tunnel magnetoresistive (TMR) element film in which a
tunnel barrier layer 1B.sub.2 is interposed between a free layer
1B.sub.1 and a fixed layer 1B.sub.3. A terminal RT1 and a terminal
RT2 are connected to the upper shield electrode 1B.sub.U and the
lower shield electrode 1B.sub.L respectively. It is also possible
to employ a giant magnetoresistive (GMR) element as the MR element
1B. The structure and the material of the MR element film described
in U.S. Pat. No. 6,146,776, U.S. Pat. No. 7,283,326, and U.S. Pat.
No. 7,320,170, for example, is referred to and cited.
[0039] FIG. 5 is a block diagram of an inspection device.
[0040] A write control circuit CONT1 is connected between a
terminal WT1 and a terminal WT2 provided on either end of the coil
CL. The electrodes on either end of the MR element 1B are connected
to the terminal RT1 and the terminal RT2 respectively. The terminal
RT1 and the terminal RT2 are connected to an output monitor circuit
CONT2. The upper shield electrode and the lower shield electrode
are connected to the terminal RT1 and the terminal RT2 respectively
when the MR element 1B is a TMR element, however a GMR element can
also be used as the MR element 1B.
[0041] The heater HT is a resistance heater or an induction heater,
and a terminal HT1 and a terminal HT2 of either end of the heater
HT are connected to a heater control circuit CONT3. The temperature
of the heater HT can be directly or indirectly determined as
needed.
[0042] Write information output to the coil CL from the write
control circuit CONT1 is displayed on a display device DSP. The
output monitor circuit CONT2 applies voltage between the terminal
RT1 and the terminal RT2 of the MR element 1B, and monitors the
sense current flowing between the terminal RT1 and the terminal RT2
at the time of voltage application. The output monitor circuit
CONT2 may monitor resistance between both ends of the MR element
1B. In either case, the output signal from the MR element 1B is
detected by the output monitor circuit CONT2 and the output monitor
circuit CONT2 detects a signal component S and a noise component N
included in the output signal. The signal component S and the noise
component N are input into a calculation circuit CONT4 together
with an applied voltage V to the MR element 1B. The applied voltage
V is sequentially varied as follows: V1 equals 50 mV, V2 equals 150
mV, and V3 equals 300 mV.
[0043] Based on the input values, the calculation circuit CONT4
calculates the SN ratio obtained when the applied voltage V equals
V1, and the SN ratio obtained when the applied voltage V equals V2,
and thereby calculates the difference .DELTA.SN of these SN ratios,
and displays this on the display device DSP. Moreover, based on the
input values, the calculation circuit CONT4 calculates the SN ratio
obtained when the applied voltage V equals V2, and the SN ratio
obtained when the applied voltage V equals V3, and thereby
calculates the difference .DELTA.SN of these SN ratios, and
displays this on the display device DSP.
[0044] (Determination Method 1)
[0045] In the determination method 1, a determination flag is set
to J, and in a case in which the applied voltage V equals V1 and
V2, the MR element is determined to be a non-defective product, in
other words "J=1," when a difference .DELTA.SN (applied voltage
V=V1, V2) calculated by the calculation circuit CONT4 is greater
than or equal to a predetermined threshold value .alpha.1, and the
MR element is determined to be a defective product, in other words
"J=0," when this difference .DELTA.SN is less than the threshold
value .alpha.1. These determination results are transmitted to a
selector SEL.
[0046] (Determination Method 2)
[0047] In the determination method 2, in a case in which the
applied voltage V equals V2 and V3, the MR element may be
determined to be a non-defective product, in other words "J=1,"
when a difference .DELTA.SN (applied voltage V=V2, V3) calculated
by the calculation circuit CONT4 is greater than or equal to a
predetermined threshold value .alpha.2, and the MR element may be
determined to be a defective product, in other words "J=0," when
this difference .DELTA.SN is less than the threshold value
.alpha.2. These determination results are transmitted to the
selector SEL.
[0048] FIG. 6 is a flow chart of the determination according to the
determination method 1.
[0049] First, a threshold value A (=.alpha.1) is set (S1). Next,
the signal component S (V1) and the noise component N (V1) obtained
when the applied voltage V to the MR element equals V1 are measured
(S2). Following this, the signal component S (V2) and the noise
component N (V2) obtained when the voltage applied V to the MR
element equals V2 are measured (S3). Next, the difference ASN of
the SN ratios (applied voltage V=V1, V2) is calculated. In other
words, the following is calculated (S4): .DELTA.SN (V=V1, V2)=201og
(S(V2)/N(V2))-201og (S(V1)-N(V1)).
[0050] Thereafter, it is determined whether the .DELTA.SN
calculated in the above-described step is greater than or equal to
the threshold value A. The MR element is determined to be a
non-defective product when the .DELTA.SN is greater than or equal
to the threshold value A (YES) (S6). On the other hand, the MR
element is determined to be a defective product when the .DELTA.SN
is less than the threshold value A (NO) (S7). After this
determination, sorting is performed by the selector SEL (S8). Note
that, although voltage V2 is set to be larger than voltage V1, the
.DELTA.SN becomes a negative value in subtraction to calculate the
.DELTA.SN when voltage V2 is smaller than voltage V1. To prevent
this, the .DELTA.SN may be multiplied by a minus sign to set the
obtained positive value as a new .DELTA.SN value.
[0051] In the determination method 2, the above-described steps may
be implemented with the threshold value A set to equal .alpha.2
(.alpha.2>.alpha.1), and the applied voltages set to V2 and V3,
in place of V1 and V2.
[0052] FIG. 7 is a graph showing the relationship of an applied
voltage and .DELTA.SN.
[0053] An inspection of MR elements of sample numbers OK01 to OK05,
and FA01 to FA07, is performed at room temperature. Room
temperature is generally 40.degree. C. or less, and a temperature
of 27.degree. C. (300 K) is used in this experiment. The SN ratios
of the MR elements of the sample numbers OK01 to OK05 do not
significantly deteriorate even when the surrounding ambient
temperature is increased to a high temperature. However, the SN
ratios of the MR elements of the sample numbers FA01 to FA07
significantly deteriorate when the surrounding ambient temperature
is increased to a high temperature. The ambient temperature at a
high temperature is approximately 100.degree. C. As used herein, an
MR element in which the SN ratio significant deteriorates means an
MR element in which the SN ratio decreases by 2 dB or more in
comparison to the SN ratio at room temperature.
[0054] The MR elements used in the experiment are MR elements of a
foundation layer, an antiferromagnetic layer {IrMn (7 nm)}, a
laminated ferri-pinned layer {CoFe (3 nm)/Ru (0.8 nm)/CoFe (2 nm)},
a tunnel barrier layer {MgO (1.5 nm)}, and a free layer {CoFe (3
nm)}. Thickness is indicated in parenthesis.
[0055] An external heater can be used to increase the temperature,
however a built-in heater HT is controlled from a heater control
circuit CONT3 in the present example. The control state of the
heater HT is displayed on the display device DSP.
[0056] The .DELTA.SN values (V2=150 mV and V1=50 mV) are plotted at
a position corresponding to an applied voltage of 150 mV. The
.DELTA.SN values of the samples of the sample numbers OK01 to OK05
are all greater than or equal to the threshold value A (=.alpha.1).
The .DELTA.SN values of the samples of the sample numbers FA01 to
FA07 are all less than the threshold value A (=.alpha.1).
[0057] The .DELTA.SN values (V3=300 mV and V2=150 mV) are also
plotted at a position corresponding to an applied voltage of 300
mV. The .DELTA.SN values of the samples of the sample numbers OK01
to OK05 are all greater than or equal to the threshold value A
(=.alpha.2). The .DELTA.SN values of the samples of the sample
numbers FA01 to FA07 are all less than the threshold value A
(=.alpha.2).
[0058] A reference line B formed from a straight line having a
slope of .beta.1 can also be used to differentiate between the
samples of the sample numbers OK01 to OK05 and the samples of the
sample numbers FA01 to FA07. The reference line B passes through
the origin of an applied voltage of 0 mV. Excluding the .DELTA.SN
values at 50 mV, it is possible to determine that samples having a
.DELTA.SN greater than or equal to the value on the reference line
B are non-defective products, and that samples having a .DELTA.SN
less than the value on the reference line B are defective products.
The formula for the reference line B is as follows:
.DELTA.SN=.sym.1.times.V.
[0059] If the .DELTA.SN value on the reference line B at a voltage
of 150 mV is set to .alpha.1, and the .DELTA.SN value on the
reference line B at a voltage of 300 mV is set to .alpha.2, then
when a product is determined to be a non-defective product in both
the above-described determination method 1 and the above-described
determination method 2, the MR element is ultimately determined to
be a non-defective product, however when this is not the case, the
MR element is determined to be a defective product. It is also
possible to set the slope of .beta.1 to the average value of the
slopes of the .DELTA.SN line segments of the non-defective samples
from between the applied voltages of 50 mV to 300 mV shown in FIG.
7.
[0060] As described above, the inspection step in the method of
manufacturing a magnetic device comprises the steps of: (a)
sequentially applying a plurality of different voltages of V1, V2,
and V3 to the MR element, and sequentially detecting output signals
from the MR element, and (b) determining the MR element to be a
defective product and eliminating the MR element, when at least one
evaluation value (preferably equivalent to the .DELTA.SN) based on
the difference (the .DELTA.SN) of the SN ratios of the output
signals from the MR element obtained respectively for each applied
voltage of V1, V2, and V3, is less than a first threshold value (A
(.alpha.1)), and determining the MR element to be a non-defective
product and selecting the MR element, when the at least one
evaluation value is greater than or equal to the first threshold
value (A (.alpha.1)).
[0061] Moreover, when the number of evaluation values (preferably
the .DELTA.SN) is plural (the .DELTA.SN at 150 mV and the .DELTA.SN
at 300 mV) and an evaluation value (the .DELTA.SN at 300 mV)
different from the evaluation value at 150 mV is less than a second
threshold value (A (=.alpha.2)), the MR element is eliminated as a
defective product even if the evaluation value (the .DELTA.SN at
150 mV) in the step (b) is greater than or equal to the first
threshold value (A (=.alpha.1)).
[0062] FIG. 8 is a graph showing a relationship of a normalized
applied voltage and .DELTA.SN. The graph of FIG. 8 is obtained by
normalizing the applied voltage in the graph of FIG. 7 at the
applied voltage of V1 equaling 50 mV.
[0063] In the determination performed using the above-described
determination method 1 and/or the above-described determination
method 2, the threshold value A may be used in the same manner.
[0064] A reference line B has a slope of .beta.2, and the .DELTA.SN
is zero when the normalized applied voltage is 1 (equaling the
applied voltage of 50 mV prior to normalization). In this case,
when the normalized applied voltage is in a range larger than 1,
the samples (OK01 to OK05) having a .DELTA.SN greater than or equal
to the value on the reference line B (the slope of .beta.2) are all
determined to be non-defective products, that is "J=1," and the
samples (FA01 to FA07) having a .DELTA.SN less than the value on
the reference line B (the slope of .beta.2) are all determined to
be defective products, that is "J=0." If the value on the reference
line B is assumed as the above-described threshold value A, this
determination is identical to the above-described determination
method 1 and/or the above-described determination method 2. The
formula of the reference line B is as follows:
.DELTA.SN=(.beta.2.times.V)-.beta.2.
[0065] Note that the .DELTA.SN value may also have a correction
factor. In cases in which a correction factor according to a
measurement device, correction factors due to ambient temperature
and pressure, and so on have to be considered, it is possible to
set a new .DELTA.SN by adding/subtracting these correction factors
as needed and to set this new .DELTA.SN as the final evaluation
value. The MR element may be determined to be a non-defective
product when the evaluation value is greater than or equal to the
threshold value A, and may be determined to be a defective product
when the evaluation value is less than the threshold value A.
[0066] On the other hand, in a case in which the above-described
.DELTA.SN is not used, it is not possible to differentiate between
non-defective products and defective products at room
temperature.
[0067] FIG. 9 is a graph showing a relationship of an applied
voltage and signal component S*. In FIG. 9, the applied voltage is
normalized at 50 mV, the magnitude of the signal component S is
also normalized at a value when the applied voltage is 50 mV, and
the normalized signal component is indicated by an S*. As can be
understood from this graph, line segments indicating data of
non-defective products and line segments indicating data of
defective products are mixed, and as such non-defective products
and defective products cannot be separated based upon the data of
the signal components S* only.
[0068] FIG. 10 is a graph showing a relationship of an applied
voltage and noise component N*. In FIG. 10, the applied voltage is
normalized at 50 mV, the magnitude of the noise component N is also
normalized at a value when the applied voltage is 50 mV, and the
normalized noise component is indicated by an S*. As can be
understood from this graph, line segments indicating data of
non-defective products and line segments indicating data of
defective products are mixed, and as such non-defective products
and defective products cannot be separated based upon the data of
the noise components N* only.
[0069] FIG. 11 is a table showing data used to create the
above-described graphs, and showing the relationship of S*, N*, and
.DELTA.SN for each sample for different applied voltages. FIG. 12
is a table showing data used to create the above-described graphs,
and showing the relationship of S, N, and SN for each sample for
different applied voltages.
[0070] The steps following the above-described differentiation will
be described by referring again to FIG. 5. The selector SEL
performs an inspection of the MR element 1B included in a
manufactured product (including a semifinished product) which has
passed through a production line. When a determination result of
the calculation circuit CONT4 indicates a non-defective product,
that is "J=1," the selector SEL selects this product and transports
it to the next step, and when the determination result indicates a
defective product, that is "J=0," the selector SEL eliminates this
product thereby removing it from the production line.
[0071] As described above, the inspection device comprises the
output monitor circuit (detection means) CONT2 which sequentially
applies a plurality of different voltages to the MR element, and
sequentially detects output signals from the MR element, and a
calculation circuit (calculation means) CONT4 which determines the
MR element to be a defective product, when an evaluation value (the
.DELTA.SN) based on the difference between the SN ratios of the
output signals from the MR element respectively obtained for each
applied voltage which are detected by the output monitor circuit
CONT2, is less than the threshold value A, and determines that the
MR element to be a non-defective product when the evaluation value
(the .DELTA.SN) is greater than or equal to the threshold value A.
The results of differentiation of the calculation circuit CONT4 are
displayed on the display device DSP.
[0072] The selector SEL is, for example, formed from a robot arm.
However, it is also possible for a person to perform sorting in
this method of manufacturing.
[0073] Note that, the signal component S, and the noise component N
can be obtained in the following manner. The signal component S is
obtained by extracting a component that changes in synchronization
with a media magnetic field or an external magnetic field. The
noise component N is obtained by extracting a component not
synchronized with a magnetic field. Alternatively, an output
measured in a state in which a magnetic field is not applied may be
used as the noise component N.
[0074] When measuring the output of the MR element after assembly
of the hard disk device, a pulse-shaped output signal can be
obtained from the MR element if a magnetic disk on which
appropriate magnetic information is written is rotated, while
before assembly of the hard disk device, a magnetic field applied
to the MR element at the time of the magnetic disk rotation may be
simulatively applied to the MR element from the outside.
[0075] The above-described inspection step may be carried out at
various stages in the magnetic head manufacturing process.
[0076] FIG. 13 is a perspective view of a magnetic head bar.
[0077] A plurality of magnetic heads 21 are integrally connected
along a Y-axis and configure a magnetic head bar T21. When the
magnetic head bar T21 is diced along the dotted lines in the
drawing, each magnetic head 21 is separated, and the magnetic head
21 shown in FIG. 3 is manufactured. It is possible to implement the
inspection step for the magnetic head portion 1 once this magnetic
head bar T21 is formed. The magnetic heads 21 included in each bar
have management numbers, and after the non-defective products/the
defective products are determined in association with the
management numbers, the magnetic heads 21 determined to be
defective products are discarded following dicing.
[0078] FIG. 14 is a flow chart of a method of manufacturing.
[0079] First, a wafer in which a thin film magnetic head is formed
is manufactured (S20). Methods described in, for example, U.S.
Patent Application Publication No. 2006/0216837, and U.S. Patent
Application Publication No. 2006/0221511 are incorporated herewith
by reference as a method of forming the thin film magnetic head on
the wafer. Next, the wafer is subjected to dicing to manufacture
the bar shown in FIG. 13 (S21). Following this, the inspection step
described using FIG. 6 and the like is implemented (S22).
Furthermore, the magnetic head bar is diced, and the magnetic heads
are separated per slider substrate (S23). As for these dicing
methods, the method described in U.S. Pat. No. 6,859,678, for
example, is incorporated herewith by reference. Next, the HGA is
produced by fixing the magnetic head to the suspension with an
adhesive or the like as shown in FIG. 2 (S24). Furthermore, this
HGA is incorporated into the hard disk device, and thereby the hard
disk device shown in FIG. 1 is assembled (S25). As a method of
attaching the HGA, the methods described in, for example, U.S.
Patent Application Publication No. 2005/0200237 and U.S. Pat. No.
6,847,507 are incorporated herewith by reference.
[0080] FIG. 15 is a perspective view of the wafer.
[0081] As previously descried, the wafer W comprises the magnetic
head bars T21 integrally connected to one another. In other words,
by dicing the wafer W along the dotted lines in the drawing, the
magnetic head bar T21 shown in FIG. 6 is manufactured. The magnetic
head portion 1 is formed on the wafer W. It is possible to
implement the above-described inspection step for the magnetic head
portion 1 once the wafer W is formed. The magnetic heads 21
included in each bar T21 have management numbers, and after the
non-defective products/the defective products are determined in
association with the management numbers, the magnetic heads 21
determined to be defective products are discarded following the
dicing of the wafer or the magnetic head bar.
[0082] FIG. 16 is a flow chart of a method of manufacturing.
[0083] A TMR element is formed on the wafer W (S10), and then each
electrode is joined to the MR elements (S11). Thereafter, the
above-described inspection step is implemented (S12), and thereby
defective products are eliminated, and non-defective products are
selected. Note that, after the inspection step, the non-defective
product may be successively subjected to the above-described
remaining steps S21, S23, S24, and S25.
[0084] FIG. 17 is a flow chart of a method of manufacturing.
[0085] In this flow chart, the above-described inspection step is
implemented after the above-described steps S20, S21, S23, and S24
are successively implemented (S22). In other words, inspection is
performed in a state in which the magnetic head is attached to the
HGA, and assembly of the hard disk device is performed after
selection of the non-defective products (S25).
[0086] FIG. 18 is a flow chart of a method of manufacturing.
[0087] In this flow chart, the above-described inspection step is
implemented after the above-described steps S20, S21, S23, S24, and
S25 are successively implemented (S22). In other words, inspection
is performed in a state in which the HGA is attached to the hard
disk device, and following this the non-defective products are
sorted and then shipped.
* * * * *